Jacek Koziorowski

In vivo 19F magnetic resonance spectroscopy and chemical shift imaging of tri-fluoro-nitroimidazole as a potential hypoxia reporter in solid tumors

Purpose: 2-Nitro-α-[(2,2,2-trifluoroethoxy)methyl]-imidazole-1-ethanol (TF-MISO) was investigated as a potential noninvasive marker of tissue oxygen levels in tumors using 19F magnetic resonance spectroscopy (MRS) and 19F chemical shift imaging. Experimental Designs:In vitro data were obtained using high-performance liquid chromatography on tumor cells incubated under varying oxygen conditions to determine the oxygen-binding characteristics. In vivo data were obtained using a well-characterized hypoxic murine breast tumor (MCa), in addition to studies on a rat prostate tumor model (R3327-AT) implanted in nude mice. Detection of intratumor 19F signal from TF-MISO was done using MRS for up to 10 h following a 75 mg/kg i.v. injection. Localized distribution of the compound in the implanted MCa tumor has been imaged using slice-selective two-dimensional chemical shift imaging 6 h after injection. Results: The in vitro results showed that TF-MISO preferentially accumulates in cells incubated under anoxic conditions. The in vivo 19F MR spectral features (line width and chemical shift) were recorded as a function of time after injection, and the results indicate that the fluorine atoms are indeed sensitive to changes in the local environment while still providing a detectable MR signal. Ex vivo spectra were collected and established the visibility of the 19F signal under conditions of maximum hypoxia. Late time point (>6 h) tumor tissue concentrations, as obtained from 19F MRS, suggest that TF-MISO is reduced and retained in hypoxic tumor. The feasibility of obtaining TF-MISO tumor distribution maps in a reasonable time frame was established. Conclusions: Based on the results presented herein, it is suggested that TF-MISO has the potential to be a valid magnetic resonance hypoxia imaging reporter for both preclinical hypoxia studies and hypoxia-directed clinical therapy.

High yield direct 76Br-bromination of monoclonal antibodies using chloramine-T.

Monoclonal antibody (MAb) A33 was labeled with the positron emitter 76Br (T(1/2) = 16.2 h). Direct labeling was done using the conventional chloramine-T method. After optimization of the labeling conditions, a maximum yield (mean +/- max error) of 77 +/- 2% was obtained at pH 6.8. In vitro binding of 76Br-A33 to SW1222 colonic cancer cells showed that the immunoreactivity was retained. Also, the MAbs 38S1 and 3S193 and the peptide hEGF were 76Br-labeled, resulting in labeling yields (mean +/- max error) of 75 +/- 3%, 63 +/- 4%, and 73 +/- 0.1%, respectively. We conclude that antibodies and peptides can be labeled conveniently with 76Br for the purpose of whole-body tumour imaging by positron emission tomography.

Radiosynthesis of the iodine-124 labeled Hsp90 inhibitor PU-H71

Heat shock protein 90 (Hsp90) is an ATP dependent molecular chaperone protein whose function is critical for maintaining several key proteins involved in survival and proliferation of cancer cells. PU-H71 (1), is a potent purine-scaffold based ATP pocket binding Hsp90 inhibitor which has been shown to have potent activity in a broad range of in vivo cancer models and is currently in Phase I clinical trials in patients with advanced solid malignancies, lymphomas, and myeloproliferative neoplasms. In this report, we describe the radiosynthesis of [(124)I]-PU-H71(5); this was synthesized from the corresponding Boc-protected stannane precursor 3 by iododestannylation with [(124)I]-NaI using chloramine-T as an oxidant for 2 min, followed by Boc deprotection with 6 N HCl at 50 °C for 30 min to yield the final compound. The final product 5 was purified using HPLC and was isolated with an overall yield of 55 ± 6% (n = 6, isolated) from 3, and >98% purity and an average specific activity of 980 mCi/µmol. Our report sets the stage for the introduction of [(124)I]-PU-H71 as a potential non-invasive probe for understanding biodistribution and pharmacokinetics of PU-H71 in living subjects using positron emission tomography imaging.

A quartz-lined carbon-11 target: striving for increased yield and specific activity

INTRODUCTION The increased demand for high specific radioactivity neuroreceptor ligands for positron emission tomography (PET) requires the production of high specific radioactivity carbon-11 in high yields. We have attempted to address this issue with the development of a new quartz-lined aluminium target for the production of [(11)C]methane or [(11)C]carbon dioxide. METHODS The new target has been tested with respect to yields of [(11)C]methane and [(11)C]carbon dioxide, and the effect of the quartz liner has been evaluated. The specific radioactivities of a large number of radiopharmaceuticals produced using this target have also been measured. RESULTS The described target produces [(11)C]-labelled gases in excellent yields, and losses of radioactivity in the target on production of [(11)C]methane have been reduced significantly by the use of a quartz liner. Radiopharmaceuticals with specific radioactivities up to 9000 GBq/μmol at end of bombardment (EOB) (243 Ci/μmol) have been produced using this target. CONCLUSIONS We have developed a reliable, high-yielding carbon-11 gas target which is now routinely used in our department for the production of high specific activity radiopharmaceuticals.

Direct astatination of a peptide, human epidermal growth factor, using nido-carborane as a prosthetic group

Direct astatination of a peptide, human epidermal growth factor, using nido-carborane as a prosthetic group

Abstract 5444: Development of a noninvasive assay to determine drug concentration in tumor during hsp90 inhibitor therapy

As molecularly targeted agents assume a more prominent role in anticancer therapy there is a growing need to determine in a noninvasive manner whether the target is being engaged and to what extent such drug-target binding results in desirable effects. We address this need in the context of Hsp90, a target of significant value and one in critical need for such assessment tools, by combining a novel chemical tool selective for tumor Hsp90 with PET imaging and mathematical modeling. The chemical tool is [124I]-PU-H71, the iodine-124 radiolabeled analog of the potent Hsp90 inhibitor PU-H71, which can be administered in tracer quantities for PET imaging. The resulting diagnostic, PU-PET, has been optimized and validated preclinically in mouse models of cancer and then translated to the clinic. The exquisite design of this assay is based on three essential concepts as it relates to the target (Hsp90) as well as to the PET tracer (124I-PU-H71). First, the target is “oncogenic” Hsp90 and has been shown by numerous biochemical and pharmacokinetic studies to have a strong affinity for inhibitors and a very low koff resulting in selective and prolonged retention in tumor. Secondly, the tracer incorporates a 124I in place of the naturally occurring 127I in the structure of PU-H71 and therefore there is no change in the chemical structure. This feature in a PET tracer intended as a companion diagnostic is unprecedented and ensures that the PK properties are identical to the therapeutic agent (PU-H71). Finally, the radionuclide 124I has a four-day half-life and thus is well-suited to monitor the extended tumor retention profile observed for Hsp90 inhibitors. We here demonstrate that this PET assay informs on Hsp90 targeting in individual tumors in real time and provides accurate tumor drug concentrations for at least four chemically distinct Hsp90 drugs. In contrast, we find that plasma pharmacokinetics is not predictive of intratumor parameters and therefore provides limited value in estimating target engagement. Using PU-PET we demonstrate that at least one Hsp90 inhibitor exhibits tumor targeting and retention in humans, delivering and retaining therapeutic, micromolar, concentrations at safe doses. PU-PET is currently being evaluated in Phase 0/1 (NCT01269593) clinical trials as a noninvasive companion diagnostic to determine intratumoral concentration as well as to identify those patients who would best benefit from Hsp90 inhibitor therapy. This diagnostic assay is intended to be incorporated into future Phase 2 clinical trials in order to preselect those patients who would most likely benefit from Hsp90 inhibitor treatment. Citation Format: Tony Taldone, Nagavarakishore Pillarsetty, Mark PS Dunphy, John F. Gerecitano, Eloisi Caldas-Lopes, Brad Beattie, Radu I. Peter, Yanlong Kang, Anna Rodina, Pengrong Yan, Erica M. DaGama Gomes, Alexander Bolaender, Christina Pressl, Blesida Punzalan, Anson Ku, Thomas Ku, Smit Shah, Mohammad Uddin, Mei H. Chen, Elmer Santos, Jacek Koziorowski, Adriana Corben, Shanu Modi, Komal Jhaveri, Oscar Lin, Efsevia Vakiani, Yelena Janjigian, Pat Zanzonico, Clifford Hudis, Steven M. Larson, Jason S. Lewis, Gabriela Chiosis. Development of a noninvasive assay to determine drug concentration in tumor during hsp90 inhibitor therapy. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 5444. doi:10.1158/1538-7445.AM2015-5444